Highly conductive single-molecule junctions typically involve π-conjugated molecular bridges, whose frontier molecular orbital energy levels can be fine-tuned to best match the Fermi level of the leads. Fully saturated wires, e.g., alkanes, are typically thought of as insulating rather than highly conductive. However, in this work, we demonstrate in silico that significant zero-bias conductance can be achieved in such systems by means of topology. Specifically, caged saturated hydrocarbons offering multiple σ-conductance channels afford transmission far beyond what could be expected based upon conventional superposition laws, particularly if these pathways are composed entirely from quaternary carbon atoms. Computed conductance of molecular bridges based on carbon nanothreads, e.g., polytwistane, is not only of appreciable magnitude; it also shows a very slow decay with increasing nanogap, similarly to the case of π-conjugated wires. These findings offer a way to manipulate the transport properties of molecular systems by means of their topology, alternatively to the traditionally invoked electronic structure.
SEEK ID: https://publications.h-its.org/publications/491
DOI: 10.1021/acs.jpclett.8b03556
Research Groups: Computational Carbon Chemistry
Publication type: Journal
Journal: The Journal of Physical Chemistry Letters
Citation: J. Phys. Chem. Lett. 10(4):825-830
Date Published: 11th Feb 2019
Registered Mode: by DOI
Views: 5908
Created: 5th Nov 2019 at 13:31
Last updated: 5th Mar 2024 at 21:23
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